Chipset with near-data processing engine

ABSTRACT

A chipset with a near-data processing (NDP) engine, which uses the NDP engine to perform a command transformation and thereby to generate an input and output (I/O) command to operate a peripheral device connected to the chipset. The chipset further has a traffic control module. A Remote Direct Memory Access (RDMA) packet comes from a remote computer system and is received by the chipset to operate the peripheral device. The traffic control module directs the RDMA packet to the NDP engine to be transformed into the I/O command. The NDP engine is provided to cope with the RDMA packet.

CROSS REFERENCE TO RELATED APPLICATIONS

This Application claims priority of China Patent Application No. 201710516312.1, filed on Jun. 29, 2017, the entirety of which is incorporated by reference herein.

BACKGROUND OF THE INVENTION Field of the Invention

The present invention relates to a high-functionality chipset.

Description of the Related Art

As data storage devices have developed, there have been a lot of demands placed on how a computer system can access such a data storage device. The traditional technique of reducing the workload of the computer system's central processing unit has been to perform most of the calculations required in accessing data at the storage device end. In the traditional techniques, calculation modules designed by the vendors themselves are provided in the data storage products. In order to be compatible with different data storage products, the input and output (I/O) communication of a computer system must be quite complex.

BRIEF SUMMARY OF THE INVENTION

A near-data processing (NDP) engine is provided on a chipset of a computer system to make data storage products simple and avoid problems with compatibility.

A chipset in accordance with an exemplary embodiment of the disclosure includes a near-data processing engine and a traffic control module. The traffic control module directs a remote packet received by the chipset to the near-data processing engine. After determining that the remote packet is a remote direct memory access packet, the near-data processing engine transforms the remote direct memory access packet to an input and output command that is used in operating a peripheral device connected to the chipset. The remote direct memory access packet comes from a remote computer system.

A method in accordance with an exemplary embodiment of the disclosure for near-data processing, performed in a chipset, comprising: directing a remote packet to a near-data processing engine comprised in the chipset, determining by the near-data processing engine that whether the remote packet is a remote direct memory access packet; and if the remote packet is determined to be the remote direct memory access packet, transforming the remote direct memory access packet to an input and output command that is used in operating a peripheral device connected to the chipset by the near-data processing engine, wherein the remote direct memory access packet comes from a remote computer system.

A detailed description is given in the following embodiments with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention can be more fully understood by reading the subsequent detailed description and examples with references made to the accompanying drawings, wherein:

FIG. 1 is a block diagram depicting a computer system 100 in accordance with an exemplary embodiment of the disclosure;

FIG. 2 is a flowchart depicting how the near-data processing engine 122 of FIG. 1 implements a file system in accordance with an exemplary embodiment of the disclosure;

FIG. 3 is a flowchart depicting how the near-data processing engine 122 of FIG. 1 is used in acceleration of a database in accordance with an exemplary embodiment of the disclosure; and

FIG. 4 is a flowchart depicting how the near-data processing engine 122 of FIG. 1 copes with RDMA (abbreviated from Remote Direct Memory Access) packets transmitted from the remote computer system 112 in accordance with an exemplary embodiment of the disclosure.

DETAILED DESCRIPTION OF THE INVENTION

The following description shows exemplary embodiments of carrying out the invention. This description is made for the purpose of illustrating the general principles of the invention and should not be taken in a limiting sense. The scope of the invention is best determined by reference to the appended claims.

FIG. 1 is a block diagram depicting a computer system 100 in accordance with an exemplary embodiment of the disclosure, which includes a central processing unit (CPU) 102, a dynamic random access memory (DRAM) 104, a chipset 106 and connection ports SATA, NVMe1, NVMe2 and PCIe. The computer system 100 may further include peripheral devices (including data storage devices 108_1 to 108_3 and a network card 108_4) connected to the connection ports.

The connection ports SATA, NVMe1, NVMe2 and PCIe are input and output (I/O) terminals of the computer system 100, and each follows a transmission interface like a serial advanced technology attachment (SATA) interface, a non-volatile memory express (NVMe) interface or a peripheral component interconnect express (PCIe) interface. In another exemplary embodiment, the connection port may adopt an Ethernet technology. The data storage devices 108_1, 108_2 and 108_3 are connected to the connection ports SATA, NVMe1 and NVMe2, respectively, as peripheral devices. The data storage devices 108_2 and 108_3 may be solid state disks (SSDs). The network card 108_4 is connected to the connection port PCIe as a peripheral device. The computer system 100 connects to a network 110 via the network card 108_4 to communicate with a remote computer system 112. It should be noted that the present invention does not limit the types of peripheral devices 108_1 to 108_4. In an exemplary embodiment, a peripheral device with a SATA interface or an NVMe interface may be connected to the connection port PCIe by an adapter card rather than a network card 108_4.

In particular, there are a traffic control module 120 and a near-data processing (NDP) engine 122 built into the chipset 106. In addition to the throughput control between the peripheral devices and the core and between the peripheral devices and the system memory (DRAM), the traffic control module 120 further controls the throughput regarding communications of the near-data processing engine 122. The traffic control module 120 recognizes whether or not to use the near-data processing engine 122. The near-data processing engine 122 is used to implement a file system, or for acceleration of a database, or for responding to a remote direct memory access (RDMA) packet transmitted from the remote computer system 112.

As shown in FIG. 1, the traffic control module 120 may manage a table 124 to specify whether or not the peripheral devices 108_1 . . . 108_4 connected to the connection ports SATA, NVMe1, NVMe2, and PCIe need the operations of the near-data processing engine 122. The table 124 may be managed through a driver of the computer system 100. The near-data processing engine 122 is not used for a peripheral device operated in a “default” mode. The near-data processing engine 122 is required for a peripheral device operated in an “NDP” mode. As shown in table 124, the SATA storage device 108_1 should be operated in the default mode and the NVMe storage devices 108_2 and 108_3 and the PCIe network card 108_4 should be operated in the NDP mode. The traffic control module 120 disposed between the central processing unit 102 and the connection ports (including SATA, NVMe1, NVMe2, PCIe) transmits the received signal based on the table 124.

During a downstream cycle, the central processing unit 102 transmits signals to operate a destination peripheral device connected to one of the I/O ports. The traffic control module 120 checks the table 124. When the destination peripheral device should be operated in the NDP mode, the traffic control module 120 directs the signals transmitted from the central processing unit 102 to the near-data processing engine 122. After being processed by the near-data processing engine 122, signals (or data) are returned to the traffic control module 120. When the traffic control module 120 determines that the source of the received signal is the near-data processing engine 122, the step of checking the table 124 is skipped and, according to the destination information originally contained in the received signal, the traffic control module 120 transmits the received signal to the destination peripheral device. In contrast, when the traffic control module 120 checks the table 124 and determines that the destination peripheral device should be operated in the default mode, the signals transmitted from the central processing unit 102 are directed to the destination peripheral device by the traffic control module 120 without being passed to the near-data processing engine 122 for additional operations.

During an upstream cycle, the traffic control module 120 receives signals from a source peripheral device connected to one of the I/O ports. The traffic control module 120 checks the table 124. When the source peripheral device should be operated in the NDP mode, the traffic control module 120 directs the signals transmitted from the source peripheral device to the near-data processing engine 122. After being processed by the near-data processing engine 122, signals (or data) are returned to the traffic control module 120. When the traffic control module 120 determines that the source of the received signal is the near-data processing engine 122, the step of checking the table 124 is skipped and, according to the destination information originally contained in the received signal, the traffic control module 120 transmits the received signal to the expected destination (the central processing unit 102 or another peripheral device). In contrast, when the traffic control module 120 checks the table 124 and determines that the source peripheral device should be operated in the default mode, the signals transmitted from the source peripheral device are directed to the central processing unit 102 or another peripheral device by the traffic control module 120 without being further processed by the near-data processing engine 122 for additional operations.

As shown in FIG. 1, the near-data processing engine 122 further includes a processor 126, a data buffer 128, a cache-coherent interface 130, a pattern matching module 132 and a data compressor 134. The functions of the different modules of the near-data processing engine 122 are described below with reference to the various embodiments.

FIG. 2 is a flowchart depicting how the near-data processing engine 122 of FIG. 1 implements a file system in accordance with an exemplary embodiment of the disclosure. The computer system 100 organizes the data stored in the storage devices 108_2 and 108_3 as files. File operations requested by the central processing unit 102 are received by the traffic control module 120 in step S202. The traffic control module 120 checks the table 124 and finds that the destination peripheral device should be operated in an NDP mode. In step S204, the near-data processing engine 122 implements a file system. In an exemplary embodiment, the traffic control module 120 temporarily stores the file operations received from the central processing unit 102 in the data buffer 128. The processor 126 retrieves the file operations from the data buffer 128 via the cache-coherent interface 130, and transforms the file operations to input and output (I/O) commands and stores the input and output commands to the data buffer 128. In step S206, the traffic control module 120 receives the input and output commands read from the data buffer 128. In step S208, the traffic control module 120 directs the input and output commands to the destination peripheral device and then receives the response (e.g. raw data) from the destination peripheral device. In step S210, the near-data processing engine 122 implements a file system again. In an exemplary embodiment, the traffic control module 120 stores the response from the destination peripheral device to the data buffer 128 to be retrieved by the processor 126 via the cache-coherent interface 130 to be transformed into file data and buffered in the data buffer 128. In step S212, the traffic control module 120 receives the file data read from the data buffer 128. In step 214, the traffic control module 120 directs the file data to the central processing unit 102. In an exemplary embodiment, the traffic control module 120 regards a dynamic random access memory (DRAM) controller 140 as the destination of the file data, to use the DRAM for temporary storage of the file data.

The file system implemented by the near-data processing engine 122 provided on the chipset 106 effectively reduces the computational burden of the central processing unit 102. The central processing unit 102 only needs to simply request file operations in units of files. The resource-consuming computations of a file system are not needed to be performed by the central processing unit 102.

In an exemplary embodiment, the central processing unit 102 operates to implement a virtual file system (VFS). In this example, the near-data processing engine 122 could implement any kind of file system entity. The virtual file system commands (VFS commands) are transformed by the near-data processing engine 122 into file system management commands, which are then transformed into block input and output commands (block I/O commands).

The VFS commands at the central processing unit 102 end may include Iseek, read, write, mmap, open, ioctl . . . etc. The near-data processing engine 122 can be implemented by an Etx4fs technology for an embedded system in ARM architecture. The block I/O commands at the I/O end may include create, lookup, readpage, mknod . . . etc.

FIG. 3 is a flowchart depicting how the near-data processing engine 122 of FIG. 1 is used in acceleration of a database in accordance with an exemplary embodiment of the disclosure. For example, the computing system 100 may be used to establish a data center. The central processing unit 102 outputs database requests such as a request for space allocation “create_namespace”, a query request “get(namespace_id, key)”, a request for storing data “put(namespace_ids, keys, values, lengths)”, and so on. The transformation from database requests to input and output commands (I/O commands) are performed by the near-data processing engine 122. The operation of the database, therefore, is accelerated. In the following, a query request “get” is discussed as an example.

In step S302, the traffic control module 120 receives a query request “get” (which is a database query request) transmitted from the central processing unit 102. By checking the table 124, the traffic control module 120 finds that the destination of the query is an “NDP mode” device. In step S304, database acceleration is achieved by the near-data processing engine 122. In an exemplary embodiment, the traffic control module 120 temporarily stores the query request “get” in the data buffer 128. The processor 126 retrieves the query request “get” from the data buffer 128 through the cache-coherent interface 130 to recognize the destination SSD (solid state disk) and generate the corresponding input and output commands, and the processor 126 uses the data buffer 128 to buffer the input and output commands. In step S306, the traffic control module 120 receives the input and output commands retrieved from the data buffer 128. In step S308, the traffic control module 120 transmits the input and output commands to the destination SSD, and the destination SSD returns the queried data back to the traffic control module 120. In step S310, the near-data processing engine 122 accelerates the operation of the database again. In an exemplary embodiment, the traffic control module 120 temporarily stores the queried data in the data buffer 128. The processor 126 retrieves the queried data from the data buffer 128 through the cache-coherent interface 130 to transform the queried data into a format that is compatible with the central processing unit 102, and uses the data buffer 128 to buffer the queried data that has been transformed into a format that is compatible with the central processing unit 102. The queried data that has been transformed into the appropriate format is read from the data buffer 128 by the traffic control module 120 in step S312, and is directed to the central processing unit 102 by the traffic control module 120 in step S314. In an exemplary embodiment, the traffic control module 120 regards a dynamic random access memory (DRAM) controller 140 as the destination of the queried data, to use the DRAM for temporary storage of the queried data.

The database acceleration achieved by the near-data-side processing engine 122 within the chipset 106 effectively reduces the computational burden of the central processing unit 102 and does not require significant changes on data storage devices. The chipset 106 has high compatibility.

FIG. 4 is a flowchart depicting how the near-data processing engine 122 of FIG. 1 copes with RDMA (abbreviated from Remote Direct Memory Access) packets transmitted from the remote computer system 112 in accordance with an exemplary embodiment of the disclosure. The computer system 100 receives the RDMA packets from the network 110 via the network card 108_4 that is operating in the “NDP mode”. The target of the RDMA packets is the local memories of the computer system 100, such as the storage device 108_2 or 108_3 (SSD) which is designed to be operated in the “NDP mode”. Remote read operations are discussed below.

In step S402, the traffic control module 120 receives the RDMA packets from the network card 108_4, and checks the table 124 to determine that the network card 108_4 should be operated in the “NDP mode”. In step S404, the near-data processing engine 122 operates to implement the remote direct memory access (RDMA). In an exemplary embodiment, the traffic control module 120 temporarily stores the RDMA packets in the data buffer 128. The content stored in the data buffer 128 is checked through the cache-coherent interface 130 by the pattern matching module 132 and a confirmation is made (by checking the Hash values contained in the RDMA packets) about whether there are any RDMA packets and whether the RDMA packets are requesting to read the local SSD 108_2 which is also operated in the “NDP mode”. The processor 126 receives the RDMA packets from the data buffer 128 through the cache-coherent interface 130, transforms the RDMA packets into NVMe commands, and uses the data buffer 128 to buffer the NVMe commands. The NVMe commands are requested to operate the local SSD. In step S406, the traffic control module 120 receives the NVMe commands read from the data buffer 128. In step S408, the traffic control module 120 directs the NVMe commands to the SSD 108_2 and the SSD 108_2 returns the requested data to the traffic control module 120. Note that it is indicated in one field of the NVMe command that the destination of the NVMe command is the SSD 108_2 and, according to this field, the traffic control module 120 directs the NVMe commands to the SSD 108_2. In step S410, the near-data processing engine 122 operates to implement the remote direct memory access (RDMA) again. In an exemplary embodiment, the traffic control module 120 temporarily stores the data retrieved from the SSD 108_2 in the data buffer 128. The content stored in the data buffer 128 is read and packed by the processor 126 through the cache-coherent interface 130, and then stored back in the data buffer 128 as data packets. In step S412, the traffic control module 120 read the data packets from the data buffer 128. In step S414, the traffic control module 120 passes the data packets to the network card 108_4 and the data packets are transmitted to the remote computer system 112 via the network 110.

Remote direct memory access is implemented between the computer system 100 and the remote computer system 122 by the near-data processing engine 122 provided within the chipset 106. The central processing unit 102 does not intervene in the data exchange between the SSD 108_2 and the remote computer system 112.

It is noted that when it is confirmed by the pattern matching module 132 that the packets from the network card 108_4 are not RDMA packets, the traffic control module 120 directs the received packets to the central processing unit 102 to be processed by the central processing unit 102.

When the target of an RDMA packet received via the network card 108_4 is not the local storage device 108_2 or 108_3, the pattern matching module 132 generates a returned packet which contains a tag that clearly indicates the target of the received RDMA packet. The pattern matching module 132 uses the data buffer 128 to buffer the returned packet and then the processor 126 transmits the returned packet to the traffic control module 120 through the cache-coherent interface 130. The traffic control module 120 transmits the returned packet via the network card 108_4 to the correct target according to the tag contained in the returned packet. For example, when determining that the received RDMA packet is for accessing a peripheral device at a third end (not managed by the computer system 100 or the remote computer system 112), the pattern matching module 132 generates a returned packet that contains a tag indicating the third end. The pattern matching module 132 uses the data buffer 128 to buffer the returned packet and then the processor 126 transmits the returned packet to the traffic control module 120 through the cache-coherent interface 130. The traffic control module 120 transmits the returned packet via the network card 108_4 to the third end according to the third-end tag contained in the returned packet.

The data compressor 134 is an optional module in the near-data processing engine 122, which communicates with the processor 126 and the data buffer 128 via the cache-coherent interface 130. The data compressor 134 is operative to perform data compression for the target peripheral device or decompression of the commands or requests issued by the central processing unit 102. The near-data processing engine 122 may further include a module for data encryption and decryption (not shown in the figure), which communicates with the processor 126 and the data buffer 128 via the cache-coherent interface 130 and is operative to perform data encryption and decryption for the target peripheral device or data encryption and decryption of the commands or requests issued by the central processing unit 102.

While the invention has been described by way of example and in terms of the preferred embodiments, it should be understood that the invention is not limited to the disclosed embodiments. On the contrary, it is intended to cover various modifications and similar arrangements (as would be apparent to those skilled in the art). Therefore, the scope of the appended claims should be accorded the broadest interpretation so as to encompass all such modifications and similar arrangements. 

What is claimed is:
 1. A chipset, comprising: a near-data processing engine; and a traffic control module, directing a remote packet received by the chipset to the near-data processing engine, wherein: after determining that the remote packet is a remote direct memory access packet, the near-data processing engine transforms the remote direct memory access packet to an input and output command that is used in operating a peripheral device connected to the chipset; and the remote direct memory access packet comes from a remote computer system.
 2. The chipset as claimed in claim 1, wherein: the near-data processing engine includes a data buffer, a pattern matching module and a processor; and the traffic control module uses the data buffer to buffer the remote direct memory access packet received by the chipset to be checked by the pattern matching module; when the pattern matching module determines that the remote direct memory access packet is for operating the peripheral device, the processor transforms the remote direct memory access packet to the input and output command and transmits the input and output command to the traffic control module to be directed to the peripheral device by the traffic control module.
 3. The chipset as claimed in claim 2, wherein: after directing the input and output command to the peripheral device, the traffic control module uses the data buffer to buffer a response from the peripheral device; and the processor packs the response buffered in the data buffer as a data packet, and the traffic control module directs the data packet to the remote computer system.
 4. The chipset as claimed in claim 2, wherein: the traffic control module uses the data buffer to buffer the remote direct memory access packet to be checked by the pattern matching module; when determining that the remote direct memory access packet is for operating another peripheral device at a third end, the pattern matching module generates a returned packet that contains a tag indicating the third end and uses the data buffer to buffer the returned packet; and the processor transmits the returned packet buffered in the data buffer to the traffic control module to be directed to the third end by the traffic control module.
 5. The chipset as claimed in claim 2, wherein: the traffic control module uses the data buffer to buffer the remote packet transmitted from the remote computer system to be checked by the pattern matching module; when the pattern matching module determines that the remote packet is not the remote direct memory access packet, the processor transmits the remote packet back to the traffic control module to be directed to a central processing unit connected to the chipset by the traffic control module.
 6. The chipset as claimed in claim 2, wherein: the near-data processing engine further provides a cache-coherent interface; and the processor accesses the data buffer and operates the pattern matching module through the cache-coherent interface.
 7. The chipset as claimed in claim 6, wherein: the near-data processing engine further includes a data compressor operative to perform data compression for the peripheral device; and the processor operates the data compressor via the cache-coherent interface.
 8. The chipset as claimed in claim 6, wherein: the near-data processing engine further includes an encryption and decryption module operative to perform data encryption and decryption for the peripheral device; and the processor operates the encryption and decryption module via the cache-coherent interface.
 9. The chipset as claimed in claim 1, wherein: the traffic control module provides throughput control on data transmitted to the near-data processing engine; and the traffic control module also provides throughput control between a default-mode peripheral device and a central processing unit, wherein communication between the default-mode peripheral device and the central processing unit does not pass through the near-data processing engine.
 10. The chipset as claimed in claim 9, wherein: the traffic control module includes a table indicating an operation mode of a network card connected to the chipset, wherein the remote direct memory access packet is received by the chipset via the network card; when receiving the remote direct memory access packet, the traffic control module checks the table; and when the traffic control module finds from the table that the network card is operated in a near-data processing mode, the traffic control module directs the remote direct memory access packet to the near-data processing engine.
 11. The chipset as claimed in claim 10, wherein: the traffic control module also directs a response that the peripheral device made in response to the remote direct memory access packet to the near-data processing engine.
 12. The chipset as claimed in claim 1, wherein: the peripheral device is a storage device with a nonvolatile memory express interface; and the input and output command is a nonvolatile memory express command.
 13. The chipset as claimed in claim 1, wherein: when determining that the remote packet is the remote direct memory access packet and that the remote direct memory access packet is for operating the peripheral device, the near-data processing engine transforms the remote direct memory access packet to the input and output command.
 14. The chipset as claimed in claim 1, wherein: when determining that the remote packet is the remote direct memory access packet and that the remote direct memory access packet is for operating another peripheral device at a third end, the near-data processing engine generates a returned packet that contains a tag indicating the third end, and the traffic control module directs the returned packet to the third end.
 15. The chipset as claimed in claim 1, wherein: when determining that the remote packet is not the remote direct memory access packet, the near-data processing engine transmits the remote packet back to the traffic control module to be directed to a central processing unit connected to the chipset.
 16. A method for near-data processing, performed in a chipset, comprising: directing a remote packet to a near-data processing engine comprised in the chipset; determining by the near-data processing engine that whether the remote packet is a remote direct memory access packet; and if the remote packet is determined to be the remote direct memory access packet, transforming the remote direct memory access packet to an input and output command that is used in operating a peripheral device connected to the chipset by the near-data processing engine, wherein the remote direct memory access packet comes from a remote computer system.
 17. The method as claimed in claim 16, wherein: if the remote packet is not determined to be the remote direct memory access packet, directing the remote packet to a central processing unit connected to the chipset. 